FI105372B - Identification of the TRAU frame in a cellular system - Google Patents

Description

105372 Identifying a TRAU frame in a cellular system

Field of the Invention

The invention relates to a method for identifying a TRAU frame in a mobile communication system comprising a network part and at least one subscriber terminal radio communicating with the 5 network parts, the subscriber terminal normally transmitting a speech frame to be placed in the TRAU frame, and the subscriber terminal transmitting to the frame, and each TRAU frame is identified in the network section based on the sum of 10 bits of the SID codeword as a speech frame, SID frame, or SID frame corrupted on the radio path.

Background of the Invention

A problem with the above arrangement is that in the network part, the corrupted SID frame transmitted by the subscriber terminal can be mistakenly interpreted as a speech frame. This causes interference to the listener on the fixed-line telephone, in the form of a nasty "buzz" sound - · '.

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v: The problem is that, in GSM specifications, this identification is »» »poorly designed and thus cannot cope well with S-20s due to corrupted inter-20s.

When switching from normal transmission to discontinuous transmission, the SID frame is transmitted immediately after the last speech frame in accordance with the GSM specification. If the SID frame is now corrupted on the radio path, it will be interpreted as a speech frame and the interference will be heard in a single "hiss" towards the listener.

Brief Description of the Invention

It is therefore an object of the invention to provide a method and a method. implementing hardware so that the above problems can be resolved. This one. , ·. is achieved by a method of the type described in the introduction, which is characterized by the fact that, in addition to the bits of the SID code word, V is added to the sum. 30 Bits normally containing speech information in the TRAU frame, except for SID parameter bits describing the background noise.

The invention further relates to a mobile communication system comprising a network part and at least one subscriber terminal in radio communication with the network part, the subscriber terminal normally transmitting a speech frame to be inserted into the TRAU-2 105372 frame and the subscriber terminal transmitting the discontinuous transmission to the network part TRAU frame, and which TRAU frame is identified in the channel part codec of the network section based on the sum of the bits of the SID codeword as speech frame, SID frame or SID frame corrupted on the radio path. According to the invention, the mobile telephone system is characterized in that the channel code is adapted to sum up, in addition to the bits of the SID code word, other bits normally containing speech information in the TRAU frame, except for SID parameter bits describing background noise.

Preferred embodiments of the invention are claimed in the dependent claims.

The invention is based on utilizing all of the 260 bits transmitted by the subscriber terminal set by the subscriber terminal to zero. These include, in addition to the bits of the SID codeword, other bits normally containing speech information, except for the SID parameter bits describing the background noise.

The method and system of the invention provide several advantages. Sorry for the annoying noises. No speech frame is dropped because of tur, so the quality of speech improves for the listener.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in greater detail along with preferred embodiments. With reference to the accompanying drawings, of which: "FIG. 2 shows a structure of a TRAU frame; FIG.

·. DETAILED DESCRIPTION OF THE INVENTION The present invention is suitable for use in a GSM system and in a GSM-based system, such as the DCS1800 system, in which the method according to the invention can be used to identify a TRAU frame.

·, * ·: Figure 1 illustrates interesting parts of the • • 30 intercom system. The subscriber terminal 100 has a radio connection 102 to the network part. A network component refers to an integral part of a mobile telephone system, i.e., base stations, base station controllers, mobile switching centers, transmission systems and other components occurring in the mobile telephone system.

In the network section, the radio connection 102 is a party to the base station. The most important parts of the base station are described below. Figure 1 contains only the blocks relevant to explaining the invention, but it will be apparent to one skilled in the art that the conventional base station also includes other functions and structures, which need not be further described herein. The base station may be, for example, a base station of the type used in the GSM system, however, including the modifications required by the invention.

The base station typically comprises one or more transceivers. One transceiver provides radio capacity for one TDMA frame, typically eight time slots. Figure 1 illustrates the receiving side of a base station in terms of a single receiver.

10 The frame received from the radio connection 102 through the antenna 110 is fed to a receiver 112 comprising a filter which blocks frequencies outside the desired frequency band. The signal is then converted to intermediate frequency or directly to baseband, in which form the signal is sampled and quantized in an analog / digital converter 114. The equalizer 15 116 compensates for interference, e.g., interference caused by multipath propagation.

Demodulator 118 extracts a bit stream from the equalized signal, which is transmitted to demultiplexer 120. Demultiplexer 120 separates the bit stream from different time slots into its own logical channels.

Channel codec 122 decodes the bit stream of the various logical channels, i.e.. **: 20 determines whether the bit stream is signaling information transmitted to the signaling unit (not illustrated) or whether the bit stream is speech transmitted to speech codec 124. Channel ··, 'codec 122 also performs error correction. . It is essential for the present invention to carry out the identification of the TRAU frame in the channel coder 122 as shown in connection with FIG. Preferably, the invention is implemented programmatically, whereby the invention requires only relatively simple: software changes within a strictly defined area of the channel codec 122.

· · V: The speech codec 124 performs decoding of the received data, for example, converting speech-containing data from a cellular radio network (e.g., ···. Si 13 kbit / s) to a fixed network 64 kbit / s 126. The speech codec • · 30 124 may not located in the access point, but may also be located in the access point:. *** · controller or near the mobile switching center. From the speech codec 124, the skilled artisan can use various designations such as TC (Transcoder) or TRAU (Transcoder and Rate Adapter Unit).

Figure 2 illustrates the structure of a TRAU frame. In the subscriber terminal 35, the 20 ms speech is encoded with 260 bits such that the major 50 Ia class bits and 132 lb class bits are convolutionally encoded. In addition, 4 105372 are added with error correction bits, resulting in a total of 378 bits. To these 378 bits are added the less important 78 class 78 bits. This gives a total of 456 bits, which in principle could fit into four radio bursts. However, for security reasons, they are spread over eight radio bursts 57 in 5 bit sub-blocks. Each burst is transmitted at 577 microseconds.

Channel codec 122 collects speech bits transmitted from eight consecutive bursts. The convolutional coding is decoded and the original 260 speech bits are placed in the TRAU frame.

If discontinuous transmission is used, the subscriber terminal 100 transmits the SID frame immediately at the beginning of the pause and thereafter at intervals of 480 milliseconds in one of eight successive bursts of the SID frame. With discontinuous transmission, the battery life of the mobile phone can be improved because the mobile phone transmitter is only switched on continuously when the user is speaking.

As with speech processing, the channel codec 122 collects bits transmitted from eight consecutive bursts. The convolutional coding is decompressed and the original 260 bits are placed in the TRAU frame.

The bits 0-15 of the word 0 of the TRAU frame word are always zero to separate the pe- 'j': consecutive TRAU frames. The least significant 0-bit of each of the following words 1 to 20 is always a synchronization bit of 1.

The original 260 bits received from the air interface are placed in bits 1-15 of words 2-18 of the TRAU frame and bits 1-5 of word 19.

In addition, channel codec 122 sets the values of control bits C1-C21 in bits 1-15 in word 1 and bits 6-11 in word 19. Similarly, in the codec 122, the codec 122 sets the timing bits T1 to T4 in the word 19 in bits 12-15.

«· * V: Figure 2 illustrates the 320 bits of the TRAU frame at such a moment. ' whereby the subscriber * *·· using discontinuous transmission is collected in the channel codec. a SID frame transmitted by the terminal 100 from eight bursts to one * * * · * 30 TRAU frame.

• · V *: Background tones around the subscriber terminal are described by · · now SID para metric bits S in bits 1-15 in words 2-4 and bits 1-5 in word 5.

The 95 bits of the SID codeword are already set to zero in the subscriber terminal 35 prior to transmission and are indicated in the figure by bold and italics, i.e. they are located in bits 10-11 and 13-14 of word 5, bits 1-2, 4-5, 7-5 of word 6. 105372 8, 10-11 and 13-14, etc. According to the prior art, the received TRAU frame is identified by the 95 bits of these SID codewords. Due to corruption on the radio path, some bits can go from zero to one. If the sum of the 95 bits of the SID codeword is less than two, it is concluded that it is a good SID frame. When the sum of bits is greater than or equal to two, but less than sixteen, it is a corrupt SID frame. When the sum of bits is greater than or equal to sixteen, it is a speech frame. The problem now is precisely that a badly corrupted SID frame can be interpreted as a speech frame if the sum of the bit-10 paths of the SID code word is sixteen or more.

The identification in the channel codec is signaled to the speech codec 124 by control bits C12 and C13-C14. Control bit C12 is a BFI (Bad Frame Identification) flag, which is set to one when the received frame is corrupt. The control bits C13-C14 are SID bits which indicate whether the received frame is interpreted as a speech frame (the value of bits C13-C14 is then set to zero), a SID frame (the value of bits C13-C14 is then set to second) or a corrupt SID frame (C13- The value of the C14 bits is set to • ·:, ..).

According to the invention, the sum of the bits 20 of the SID codeword are further summed with other bits normally containing the speech information of the TRAU frame, except for the SID parameter bits describing the background noise. This is • · :·. advantageous, since in the subscriber terminal these bits are also set to zero. · Pattern. section 2 describes those bits with normal zeros and is thus located in bits 6-9.12 and 15 of word 5, bits 3, 6, 9.12 and 15 of word 6, and so on.

When according to the prior art identification is performed on the basis of 95 bits of the SID * *: codeword, according to the invention identification is performed on the basis of 95 + 115 = 210 bits. This results in a much more reliable result, because momentary interference is not able to affect the identification •, ···. reliability.

., 30 As in the prior art, the invention uses a defined upper and lower limit. When the sum of the bits is V **. more than a predetermined upper limit, the recognizable TRAU frame is a speech frame. When the sum of the combined bits is less than a predetermined upper limit but greater than a predetermined lower limit, the identifiable TRAU frame is a corrupt SID frame. When the sum of the total bits is less than a predetermined lower limit, the identifiable TRAU frame is a SID frame.

However, the values of the SID bits C13-C14 are set using the limits of the prior art and not using the limits of the invention. A corrupt SID frame detected using the limits of the invention 5 is detected by setting the BFI bit C12 on. This provides the advantage that the procedure according to the GSM specification does not need to be changed. The following two examples illustrate this point.

For example, if the 210 bit sum of the decoded frame is 44 and the sum of 95 bits of the 10 SID codewords is 18, then the value of the SID bits C13-C14 in the TRAU frame is set to zero, i. a frame is a speech frame. However, according to the applicant's studies, such a speech frame with so few ones (44/210) cannot exist, but the issue must be a corrupt SID frame transmitted by the subscriber terminal. The value of the SID bits C13-C14 is thus set to zero in a known manner, i.e. a speech frame, but the frame is discarded by setting the BFI bit C12 on.

If, for example, the sum of 210 bits of the decoded frame is, for example, 10 «and the sum of 95 bits of the SID codeword is only one, then the value of the SID bits C13-C14 in the TRAU frame is set to two, i.e. frame is a good SID-Wed-20 hys. According to the applicant's studies, such a frame causes interference in the form of a · · helicopter sound, so that the frame is rejected by setting the BFI bit C12 on.

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According to the Applicant, when examining the speech coding of a GSM phone, it is found that the sum of the 210 bits in the speech frame varies approximately 80-120. In SID frames causing "collisions", the corresponding sum of 210 bits * * 'in the tests has been approximately 25-60.

• «·: According to the applicant's studies, the upper limit is thus between 60 and 80 and the lower limit is between 5 and 10. The upper limit is most preferably about 65. The lower limit is most preferably about 8.

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In one preferred embodiment, the sum * * *, in addition to the bits of the * 30 SID codeword, are added to other conventionally convolutional coded I class bits in the TRAU frame, except for the SID parameter bits describing the background noise. In another preferred embodiment, the sum adds, in addition to the bits of the SID codeword, other non-conventional convolutional coding bits of the class II containing the speech information of the TRAU, except for the SID parameter bits describing the background noise. The upper and lower limits to be used in both of these 7 105372 embodiments must be determined by study.

Although the invention has been described above with reference to the example of the accompanying drawings, it is to be understood that the invention is not limited thereto but that it can be modified in many ways within the scope of the inventive idea set forth in the appended claims.

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Claims (24)

A method for detecting a TRAU frame in a mobile communication system comprising a network portion and at least one subscriber terminal radio communicating with the network portion, and the subscriber terminal transmitting a speech frame normally placed in the TRAU frame to the network portion and transmitting to the a SID frame to be placed in a frame, and which TRAU frame is identified in the network section based on the sum of the bits of the SID codeword as a speech frame, SID frame or SID key 10 corrupted on the radio path, characterized in that Bits normally containing speech information in the TRAU frame except SID parameter bits for background noise. Method according to claim 1, characterized in that the 95 bits of the SID code word are located in words 5-19 of the TRAU frame, and the 50 SID parameter bits representing the background noise are located in words 2-5 of the TRAU frame and the rest of the TRAU frame normally contains • , .. - 115 bits are located in words 2-19 of the TRAU frame. A method according to claim 1, characterized in that, when using discontinuous transmission, the subscriber terminal bits of the SID code word 20 and other bits normally containing speech information of the TRAU frame are set to zero. «« * Method according to claim 1, characterized in that: · · That if the sum of the total bits is greater than a predetermined upper limit, the identifiable TRAU frame is a speech frame. i *** 25 A method according to claim 1, characterized in that, if the sum of the bits in the sum is less than a predetermined upper limit but greater than a predetermined lower limit, then the recognizable •, · * ·. The TRAU frame is a corrupt SID frame. The method of claim 1, characterized in that, when the sum of the bits added is less than a predetermined V *: lower bound, the TRAU frame to be recognized is the SID frame. Method according to one of the preceding claims 4 to 6, characterized in that the upper limit is between 60 and 80. A process according to claim 7, characterized in that the upper limit is most preferably about 65. 105372 g 8 105372 Method according to one of the preceding claims 4 to 6, characterized in that the lower limit is between 5 and 10. The method of claim 9, wherein the lower limit is most preferably about 8. 11. A method according to claim 1, characterized by summing, in addition to the bits of the SID codeword, other class I bits normally protected by convolutional coding of the TRAU, except for the SID parameter bits describing the background noise. A method according to claim 1, characterized in that, in addition to the bits of the SID codeword, other non-convolutional Class II non-convolutional bits of the TRAU, other than SID parameter bits describing background noise, are added to the sum. 13. A cellular telephone system comprising a network part and at least one subscriber terminal radio-communicating with the network part, and the subscriber terminal device normally transmits a speech frame to be placed in the TRAU frame to the network part, and the subscriber terminal transmits The SID frame, and each TRAU frame is identified in the channel codec of the network section based on the sum of the v-bits of the SID codeword as a speech frame, SID frame, or radio «4« '·. 20 path to a corrupt SID frame, characterized in that the channel codec is adapted to sum up, in addition to the bits of the SID codeword, other bits normally containing speech information in the TRAU frame, except for -; *; SID parameter bits for noise. 14. A cellular telephone system as claimed in claim 13, characterized in that 95 bits of the SID code word are located in words 5-19 of the TRAU frame, and 50 SID parameter bits representing background noise are located in words 2-5 of the TRAU frame. and the rest of the 115 bits normally containing speech information of the TRAU frame are located in words 2-19 of the TRAU frame. Cellular telephone system according to claim 13, characterized in that, when discontinuous transmission is used, the subscriber terminal's • 44 * bits of the SID code word and other bits containing normal speech information '* of the TRAU frame except SID parameter bits describing background noise are set to zero. capsule. 16. A cellular telephone system according to claim 13, characterized in that the channel codec is adapted such that, when the sum of the total bits is greater than a predetermined upper limit, the identifiable TRAU frame is a speech frame. The mobile telephone system of claim 13, characterized in that the channel codec is adapted such that, when the sum of the bits is less than a predetermined upper limit but greater than a predetermined lower limit, the identifiable TRAU frame is a corrupt SID frame. 18. The cellular telephone system of claim 13, characterized in that the channel codec is adapted such that, when the sum of the total bits is less than a predetermined lower limit, the TRAU frame to be recognized is the SID frame. A mobile telephone system according to any one of claims 16 to 18, characterized in that the upper limit is between 60 and 80. The mobile telephone system of claim 19, characterized in that the upper limit is most preferably about 65. A cellular telephone system according to any one of claims 16 to 18, characterized in that the lower limit is between 5 and 10. The mobile telephone system of claim 21, characterized in that the lower bound is most preferably about 8. 23. A cellular telephone system according to claim 13, characterized in that the channel codec is adapted to sum up, in addition to the bits of the SID codeword, other conventional convolutional coded I class bits containing conventional speech information in the TRAU frame, except for SID parameter bits describing background noise. 24. A cellular telephone system according to claim 13, characterized in that the channel codec is adapted to add to the sum, in addition to the bits of the SID code word, other non-convolutional non-convolutional bits of class II containing the TRAU frame ** except background i *]]: noise SID parameter bits. • * «· · t ·« • · * t • · · «·« • 11 105372